Systems and methods for treating tissue with radiofrequency energy

ABSTRACT

A system for controlling operation of a radiofrequency treatment device to apply radiofrequency energy to tissue to heat tissue to create lesions without ablating the tissue. The system includes a first treatment device having at least one electrode for applying radiofrequency energy to tissue, a controller including a connector to which a first treatment device is coupled for use, and a generator for applying radiofrequency energy to the electrodes. The controller controls application of energy so that the tissue is thermally treated to create lesions but preventing thermal treatment beyond a threshold which would ablate the tissue.

RELATED APPLICATIONS

This application is a divisional of application Ser. No. 13/867,042, filed Apr. 20, 2013, now U.S. Pat. No. 9,474,565, which claims the benefit of provisional application Ser. No. 61/664,960, filed Jun. 27, 2012 and is a continuation-in-part of application Ser. No. 12/924,155, filed Sep. 22, 2010, now abandoned, which claims the benefit of provisional application Ser. No. 61/277,260 filed Sep. 22, 2009. The entire contents of each of these applications are incorporated herein by reference.

FIELD OF THE INVENTION

In a general sense, the invention is directed to systems and methods for treating interior tissue regions of the body. More specifically, the invention is directed to systems and methods for treating dysfunction in body sphincters and adjoining tissue by applying radiofrequency energy to tissue to create tissue lesions without ablating tissue.

BACKGROUND OF THE INVENTION

The gastrointestinal (GI) tract, also called the alimentary canal, is a long tube through which food is taken into the body and digested. The alimentary canal begins at the mouth, and includes the pharynx, esophagus, stomach, small and large intestines, and rectum. In human beings, this passage is about 30 feet (9 meters) long.

Small, ring-like muscles, called sphincters, surround portions of the alimentary canal. In a healthy person, these muscles contract or tighten in a coordinated fashion during eating and the ensuing digestive process, to temporarily close off one region of the alimentary canal from another region of the alimentary canal.

For example, a muscular ring called the lower esophageal sphincter (or LES) surrounds the opening between the esophagus and the stomach. Normally, the lower esophageal sphincter maintains a high-pressure zone between fifteen and thirty mm Hg above intragastric pressures inside the stomach.

In the rectum, two muscular rings, called the internal and external sphincter muscles, normally keep fecal material from leaving the anal canal. The external sphincter muscle is a voluntary muscle, and the internal sphincter muscle is an involuntary muscle. Together, by voluntary and involuntary action, these muscles normally contract to keep fecal material in the anal canal.

Dysfunction of a sphincter in the body can lead to internal damage or disease, discomfort, or otherwise adversely affect the quality of life. For example, if the lower esophageal sphincter fails to function properly, stomach acid may rise back into the esophagus. Heartburn or other disease symptoms, including damage to the esophagus, can occur. Gastrointestinal reflux disease (GERD) is a common disorder, characterized by spontaneous relaxation of the lower esophageal sphincter.

Damage to the external or internal sphincter muscles in the rectum can cause these sphincters to dysfunction or otherwise lose their tone, such that they can no longer sustain the essential fecal holding action. Fecal incontinence results, as fecal material can descend through the anal canal without warning, stimulating the sudden urge to defecate. The physical effects of fecal incontinence (i.e., the loss of normal control of the bowels and gas, liquid, and solid stool leakage from the rectum at unexpected times) can also cause embarrassment, shame, and a loss of confidence, and can further lead to mental depression.

In certain surgical systems, radiofrequency energy is applied to tissue at different tissue levels to create multiple tissue lesions. Application of such energy requires continuous monitoring of certain tissue and/or device parameters to ensure that the tissue is not heated to such extent that damaging burning of tissue occurs. Thus, these systems monitor tissue temperature and/or device electrode temperature and provide safety features to cut off energy flow if the tissue temperature rises too high. However, with the application of radiofrequency energy, there is a fine point in which tissue is treated to form lesions and beneficially alter structure of the tissue, e.g., alter the structure of the sphincter muscle, while not being ablated or burned.

Ablation of tissue can be generally defined as a removal of a part of tissue. Radiofrequency energy to ablate tissue has been used for various tumor treatments, destroying tissue and creating tissue necrosis. However, avoiding tissue ablation may be beneficial in treating the gastrointestinal tract in the foregoing or other procedures. Therefore, it would be advantageous to provide a system of applying radiofrequency energy to tissue at a power setting and time duration which causes thermal effect to tissue to create tissue lesions along a series of tissue levels but avoids ablation or burning of tissue.

However, in avoiding tissue ablation, care needs to be taken to ensure that tissue is not undertreated. In other words, in attempts to prevent overheating of tissue which causes ablation, the system needs to conversely ensure that tissue is not under-heated and thus not therapeutically treated. Therefore, the need exists for a system that applies radiofrequency energy to tissue between these two energy levels.

SUMMARY OF THE INVENTION

The present invention advantageously provides an electrosurgical system that applies radiofrequency energy to tissue to create tissue lesions at different tissue levels and alters the structure of the tissue, e.g., the sphincter muscle, without ablating or burning the tissue, while on the other hand reducing the incidence of tissue undertreatment. This is achieved in one aspect by accurate calibration of the tissue temperature measurement mechanism and improvement of appropriate reading and response to high tissue temperatures. This is achieved in another aspect by improved application of cooling fluid to the tissue during the surgical procedure to provide quick response to rising tissue temperatures. This is achieved in still another aspect by placement of data collection hardware in the treatment device, closer to the source. This is achieved in yet another aspect by providing a visual warning to the user of too high a temperature as soon as the needle electrodes are deployed before energy is applied. In yet another aspect, accurate spacing of tissue level treatments is achieved to reduce overlapping of energy application.

Moreover, the present invention advantageously provides such electrosurgical system that avoids such overheating of tissue, while at the same time limiting under-heating of tissue which does not effectively treat tissue. Thus, in striking this balance between the overheating and under heating of tissue, more reliable and consistent tissue treatment is achieved.

This prevention of undertreatment is achieved in various ways, all designed to avoid disabling/cut off of energy to the electrodes if such cutoff is not warranted. In one aspect, avoidance of undertreatment is achieved by more accurate temperature reading due to placement of the data collecting hardware in the surgical treatment device and shielding the hardware, thereby reducing susceptibility to noise which can disrupt communication and reporting this collected data to the controller/generator. In another aspect, a multiple checking of errors confirms that energy cutoff is really warranted.

The foregoing different aspects utilized to achieve the desired tissue treatment can be implemented alone or in combination with each other.

Thus, the system and method of the present invention advantageously keeps tissue treatment within a target zone to provide a therapeutic effect to tissue, defined as thermally heating tissue above a lower parameter wherein tissue is undetreated and below a tissue ablation threshold wherein tissue is overheated and ablated.

In one embodiment of the present invention a system for controlling operation of a radiofrequency treatment device to apply radiofrequency energy to tissue to heat tissue to create tissue lesions without ablating the tissue is provided. The system includes a first treatment device having at least one electrode for applying radiofrequency energy to tissue, a controller including a connector to which a first treatment device is coupled for use, and a generator for applying radiofrequency energy to the electrodes. The controller controls application of energy so that the tissue is thermally treated to create lesions but prevents thermal tissue. The controller can further include an operation system to execute on a display screen a first graphical interface guiding use of the first treatment device, the controller visually prompting a user in a step-wise fashion to perform a process using the connected treatment device of forming a pattern of lesions in a body region in a plurality of axially spaced lesion levels, each lesion level including a plurality of circumferential spaced lesions.

In some embodiments, the treatment device includes a handle and a shielded printed circuit board contained in the handle, the printed circuit board enabling precise measurement of tissue and electrode parameters to regulate tissue temperature to prevent thermal treatment of tissue beyond the threshold, and the shield reducing interference.

In some embodiments, the controller automatically increases the flow of cooling fluid to the tissue if a tissue temperature exceeds a predetermined value to thereby reduce the tissue temperature to prevent thermal treatment of tissue beyond the threshold.

In some embodiments, the printed circuit board is calibrated in manufacture to improve the temperature accuracy to prevent thermal treatment of tissue beyond the threshold.

In another embodiment, the present invention provides a method of treating fecal incontinence comprising the steps of:

providing a treatment device having a plurality of electrodes;

applying radiofrequency energy to the electrodes to thermally treat tissue below a tissue ablation threshold and create a plurality of tissue lesions along axially spaced tissue levels within the anal canal;

monitoring tissue temperature throughout the procedure; and

regulating power ensuring in response to the monitoring step that the tissue temperature does not exceed a predetermined value which would cause tissue ablation and/or tissue necrosis.

In some embodiments, the ensuring step is achieved by providing an automatic cooling system to apply cooling fluid to the tissue if a measured temperature exceeds a predetermined value.

In some embodiments, the ensuring step is achieved by placement of a printed circuit board in a handle of the treatment device so tissue temperature monitoring occurs closer to the target tissue to thereby improve accuracy of temperature reading.

In some embodiments, the ensuring step is achieved by placement of a printed circuit board adjacent to and external of a handle of the treatment device so tissue temperature monitoring occurs closer to target tissue to thereby improve the accuracy of temperature reading.

In some embodiments, the printed circuit board is calibrated in manufacture to improve the accuracy of the temperature reading.

In another embodiment, the present invention provides a method of treating gastrointestinal reflux disease comprising the steps of:

providing a treatment device having a plurality of electrodes;

applying radiofrequency energy to the electrodes to thermally treat tissue below a tissue ablation threshold and create a plurality of tissue lesions along axially spaced tissue levels within the upper gastrointestinal tract;

monitoring tissue temperature throughout the procedure; and

regulating power ensuring in response to the monitoring step that the tissue temperature does not exceed a predetermined value which would cause tissue ablation and/or tissue necrosis.

In some embodiments, the ensuring step is achieved by providing an automatic cooling system to apply cooling fluid to the tissue if a measured temperature exceeds a predetermined value.

In some embodiments, the ensuring step is achieved by placement of a printed circuit board in a handle of the treatment device so tissue temperature monitoring occurs closer to target tissue to thereby improve the accuracy of temperature reading.

In some embodiments, the ensuring step is achieved by placement of a printed circuit board adjacent to and external of a handle of the treatment device so temperature monitoring occurs closer to target tissue to thereby improve the accuracy of temperature reading.

In some embodiments, the printed circuit board is calibrated in manufacture to increase accuracy of the temperature reading.

The present invention also provides in another aspect a method of a treating tissue by applying non-ablative radiofrequency energy comprising the steps of providing an instrument with a plurality of electrodes;

placing the electrodes near a sphincter to be treated; and

applying through the electrodes radiofrequency energy which is a) sufficient to increase the smooth muscle to connective tissue without changes to the collagen I/III ratio to thereby remodel the sphincter but b) insufficient to ablate the tissue.

In some embodiments, the application of radiofrequency energy reinforces the sphincter.

In some embodiments, the step of providing the electrodes near the sphincter provides the electrodes near the internal anal sphincter.

The present invention also provides in another aspect a system for controlling operation of a radiofrequency treatment device to apply radiofrequency energy to tissue to heat tissue to create lesions at a treatment range defined between under heating tissue to fail to achieve a therapeutic affect and overheating tissue to cause tissue ablation. The system comprises a controller including a connector to which a first treatment device having a plurality of electrodes for applying radiofrequency energy to tissue is coupled for use, and a generator for applying radiofrequency energy to the electrodes. The improvement comprises a multiple error checking system which if an error is detected which indicates disabling of an electrode of the treatment device, the system checks for a repeat of the error and determines if disabling is warranted or energy application is warranted to thereby reduce the likelihood of under treatment of tissue.

In some embodiments, the multiple error checking system repeats the error check three times.

The present invention also provides in another aspect a system for controlling operation of a radiofrequency treatment device to apply radiofrequency energy to tissue to heat tissue to create tissue lesions at a treatment range defined between overheating tissue to cause ablation and under heating tissue to fail to achieve a therapeutic effect. The system comprises a controller including a connector to which a first treatment device having a plurality of electrodes for applying radiofrequency energy to tissue is coupled for use, and a generator for applying radiofrequency energy to the electrodes. The controller controls application of energy so that the tissue is thermally treated to create tissue lesions but prevents thermal treatment beyond a threshold which would ablate the tissue. The system further includes a cut off feature to cut off energy flow to disable an electrode if one of multiple potential errors is detected, the system further containing a feature to prevent premature disabling of an electrode.

In some embodiments, the feature to prevent premature disabling of an electrode comprises a multiple error check in which if an error is detected, a measurement is rechecked to determine if the error is still present before cut off of energy flow.

In some embodiments, the system further comprises an automatic pump system to increase the flow of cooling fluid if measured temperature exceeds a predetermined value.

In some embodiments, the system further comprises an operation system to execute on a display screen a first graphical interface guiding use of the first treatment device coupled to the controller, the controller visually prompting a user in a step-wise fashion to perform a process using the couple treatment device of forming a pattern of lesions in a body region in a plurality of axially spaced lesion levels, each lesion level including a plurality of circumferential spaced lesions

In some embodiments of such systems and methods, a graphical display is provided for visually prompting a user in a step-wise fashion to use a treatment device to perform a process of forming a pattern of lesions in a body region comprising a plurality of axially spaced lesion levels, each lesion level comprising a plurality of circumferential spaced lesions. The systems and methods include registering the formation of lesions as they are generated in real time, both within and between each circumferentially spaced level, whereby the graphical display displays for the user a visual record of the progress of the process from start to finish and guides the user so that individual lesions desired within a given level are all formed, and that a given level of lesions is not skipped.

In some embodiments, the systems and methods include generating at each lesion level a first stylized graphical image with a number identification of its level, and generating a second stylized graphical image, different from the first stylized graphical image, generated when the formation of lesions at a given level is indicated and further showing the number of lesions to be formed at that level. The systems and methods include changing the second graphical image to a third graphical image, different than the first or second images, including added indicia to reflect the formation of lesions in real time. The systems and methods may further include generating a marker that directs the user to the next lesion level to be treated and that is updated as successive lesion levels are treated.

Further features and advantages of the inventions are set forth in the following Description and Drawings, as well as in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic view of a unified system usable in association with a family of different treatment devices for treating body sphincters and adjoining tissue regions in different regions of the body.

FIG. 2 is a perspective view, with portions broken away, of one type of treatment device usable in association with the system shown in FIG. 1 to treat tissue in the upper gastro-intestinal tract, the treatment device having an operative element for contacting tissue shown in a collapsed condition.

FIG. 2A is a perspective view of an alternate embodiment of the treatment device of FIG. 2.

FIG. 2B is a perspective view of another alternate embodiment of the treatment device of FIG. 2.

FIG. 3 is a perspective view, with portions broken away, of the device shown in FIG. 2, with the operative element shown in an expanded condition.

FIG. 4 is a perspective view, with portions broken away, of the device shown in FIG. 2, with the operative element shown in an expanded condition and the electrodes extended for use.

FIG. 5 is a lesion pattern that can be formed by manipulating the device shown FIGS. 2 to 4 in the esophagus at or near the lower esophageal sphincter and in the cardia of the stomach, comprising a plurality of axially spaced lesion levels, each lesion level comprising a plurality of circumferential spaced lesions.

FIG. 6 is a perspective view of another type of treatment device usable in association with the system shown in FIG. 1 to treat tissue in the lower gastrointestinal tract, the treatment device having an array of electrodes shown in a retracted position.

FIG. 6A is a perspective view of an alternate embodiment of the treatment device of FIG. 6.

FIG. 6B is a perspective view of another alternate embodiment of the treatment device of FIG. 6.

FIG. 7 is a perspective view of the device shown in FIG. 6, with the array of electrodes shown in their extended position.

FIG. 8 is a perspective view of the device shown in FIGS. 6 and 7, with the array of electrodes shown in their extended position deployed in the lower gastrointestinal tract to treat sphincter dysfunction in the anal canal.

FIG. 9 is a lesion pattern that can be formed by manipulating the device as shown FIG. 8 in the anal canal at or near the anal sphincter, comprising a plurality of axially spaced lesion levels, each lesion level comprising a plurality of circumferential spaced lesions.

FIGS. 10A and 10B are, respectively, left and right perspective views of one embodiment of an integrated device incorporating features of the system shown in FIG. 1 and usable with either treatment device shown in FIG. 2 or 6 for treating body sphincters and adjoining tissue regions, and also having a controller and a graphical user display for visually prompting a user in a step-wise fashion to use a treatment device to perform a process of forming a pattern of lesions in a body region like that shown in FIG. 5 or 9, to guide the user so that individual lesions desired within a given level are all formed, and that a given level of lesions is not skipped.

FIG. 11 is a representative graphical user set-up display generated by the controller prompting the user with numbers and/or text and/or icons through the set-up and connection steps prior to a treatment procedure.

FIG. 12 is a representative graphical user set-up display generated by the controller upon identifying the connection of a device like that shown in FIGS. 2 to 4 (identified by the trademark STRETTA®).

FIG. 13 is a representative graphical user set-up display generated by the controller upon identifying the connection of a device like that shown in FIGS. 6 to 8 (identified by the trademark SECCA®).

FIGS. 14-A to 14-O are representative graphical user treatment displays generated by the controller for visually prompting a user to use a treatment device like that shown in FIGS. 2 to 4 in a step-wise fashion to perform a process of forming a pattern of lesions in an esophagus like that shown in FIG. 5, the graphical user display guiding the user and creating a visual record of the progress of the process from start to finish, so that individual lesions desired within a given level are all formed, and that a given level of lesions is not skipped.

FIG. 14P illustrates graphical user displays relating to balloon inflation of the device of FIG. 3.

FIG. 14Q illustrates the display of balloon inflation icon of FIG. 14P

FIGS. 15A to 15I are representative graphical user treatment displays generated by the controller for visually prompting a user to use a treatment device like that shown in FIGS. 6 to 8 in a step-wise fashion to perform a process of forming a pattern of lesions in an anal canal like that shown in FIG. 9, the graphical user display guiding the user and creating a visual record of the progress of the process from start to finish, so that individual lesions desired within a given level are all formed, and that a given level of lesions is not skipped.

The invention may be embodied in several forms without departing from its spirit or essential characteristics. The scope of the invention is defined in the appended claims, rather than in the specific description preceding them. All embodiments that fall within the meaning and range of equivalency of the claims are therefore intended to be embraced by the claims.

DESCRIPTION OF PREFERRED EMBODIMENTS

This Specification discloses various systems and methods for treating dysfunction of sphincters and adjoining tissue regions in the body. The systems and methods are particularly well suited for treating these dysfunctions in the upper and lower gastrointestinal tract, e.g., gastro-esophageal reflux disease (GERD) affecting the lower esophageal sphincter and adjacent cardia of the stomach, or fecal incontinence affecting the internal and external sphincters of the anal canal. For this reason, the systems and methods will be described in this context. Still, it should be appreciated that the disclosed systems and methods are applicable for use in treating other dysfunctions elsewhere in the body, and dysfunctions that are not necessarily sphincter-related. For example, the various aspects of the invention have application in procedures requiring treatment of hemorrhoids, or urinary incontinence, or restoring compliance to or otherwise tightening interior tissue or muscle regions. The systems and methods that embody features of the invention are also adaptable for use with systems and surgical techniques that are catheter-based and not necessarily catheter-based.

The systems and methods disclosed herein provide application of radiofrequency energy to tissue via a plurality of electrodes. The energy is applied via the electrodes to tissue at a series of axially spaced tissue levels, thereby forming tissue lesions which alters the tissue structure. Prior application of radiofrequency energy to tissue in various surgical procedures involved application of energy at certain levels and for a certain period of time with the goal to ablate the tissue. That is, the objective was to cause tissue necrosis and remove tissue. The systems and methods of the present disclosure, however, treat tissue without ablating the tissue and without causing tissue necrosis, which advantageously achieves better clinical results, especially when treating the sphincter muscles of the GI tract in the specific surgical procedures disclosed herein. By applying sufficient energy to cause thermal effect to tissue, but without ablating or burning the tissue, tissue reconstruction/remodeling occurs which results in beneficial changes to tissue properties, thus beneficially treating GERD which is caused by the spontaneous relaxation of the lower esophageal sphincter and beneficially treating fecal incontinence caused by loss of tone of the sphincter muscles in the anal canal. The system of the present disclosure rejuvenates muscle to improve muscle function. The system of the present invention also increases the smooth muscle/connective ratio which results in sphincter reinforcement and remodeling.

In studies performed, it was found that application of non-ablative RF energy to sphincter muscle influences the structural arrangement of smooth muscle and connective tissue contents. The increase of the smooth muscle fibers area per muscle bundles as well as the collagen and myofibroblast contents within the internal anal sphincter were found to be potentially responsible for sphincter reinforcement and remodeling. More specifically, in studies, it was found that application on non-ablative RF energy increased smooth muscle/connective tissue ratio without changes (increase) in the collage I/III ratio. There was an increase in diameter and number of type I fibers in the external anal sphincter after non-ablative RF and higher cellular smooth muscle content in the internal anal sphincter, suggesting that sphincter remodeling by non-ablative RF energy resulted from activation and repopulation of smooth muscle cells, possibly related to phenotype switch of fibroblasts into myofibroblasts and external anal sphincter fibers. In one animal study, quantitative image analysis showed the cross-section occupied by smooth muscle within the circular muscle increased by up to 16& after non-ablative RF, without increase in collagen I/III ratio, and external anal sphincter muscle fiber type composition showed an increase in type I/III fiber ratio from 26.2% to 34.6% after non-ablative RF, as well as a 20% increase in fiber I type diameter compared to controls.

For such aforedescribed non-ablation RF treatment, the system and method of the present disclosure also is designed to enhance lesion creation by avoiding unnecessary cutoff energy flow to electrodes in response to a perceived error.

Various features of the controller and/or surgical treatment devices connected to the controller achieve the foregoing. Preventing overheating of tissue is achieved by enhanced temperature control of the tissue, which is accomplished in one way by more accurate temperature measurement so proper power adjustments can be made to address rising temperatures and accomplished in another way by enhanced application of cooling fluid.

Preventing undertreatment of tissue is achieved in one way by location of the data collecting hardware closer to the source and achieved in another way by ensuring error detection does not lead to premature cutoff of energy flow. Each of these are ways are described in detail below.

I. Overview of the System

FIG. 1 shows a unified system 24 for diagnosing and/or treating dysfunction of sphincters and adjoining tissue in different regions of the body. In the illustrated embodiment, the system 24 is configured to diagnose and treat dysfunction in at least two distinct sphincter regions within the body.

The targeted sphincter regions can vary. In the illustrated embodiment, one region comprises the upper gastro-intestinal tract, e.g., the lower esophageal sphincter and adjacent cardia of the stomach. The second region comprises the lower gastrointestinal tract, e.g., in the intestines, rectum and anal canal.

The system 24 includes a family of treatment devices 26 a and 26 b. Each device 26 a and 26 b can be specifically configured according to the physiology and anatomy of the particular sphincter region which it is intended to treat. The details of construction of each device 26 a and 26 b will be generally described later.

Each device 26 a/26 b carries an operative element 36 a and 36 b. The operative element 36 a and 36 b can be differently configured according to the physiology and anatomy of the particular sphincter region which it is intended to treated. Still, if the anatomy and physiology of the two treatment regions are the same or similar enough, the configuration of the operative elements 36 a and 36 b can be same or essentially the same.

In the illustrated embodiment, the operative elements 36 a and 36 b function in the system 10 to apply energy in a selective fashion to tissue in or adjoining the targeted sphincter region. The applied energy creates one or more lesions, or a prescribed pattern of lesions, below the surface of the targeted region without ablating tissue. The subsurface lesions are desirably formed in a manner that preserves and protects the surface against thermal damage.

Natural healing of the subsurface lesions leads to a reconstruction/remodeling of the tissue which leads to beneficial changes in properties of the targeted tissue. The subsurface lesions can also result in the interruption of aberrant electrical pathways that may cause spontaneous sphincter relaxation. In any event, the treatment can restore normal closure function to the sphincter region 18 as the non-ablating application of radiofrequency energy beneficially changes the properties of the sphincter muscle wall. Such energy rejuvenates the muscle to improve muscle function.

The system 24 includes a generator 38 to supply the treatment energy to the operative element 36 a/36 b of the device 26 a/26 b selected for use. In the illustrated embodiment, the generator 38 supplies radio frequency energy, e.g., having a frequency in the range of about 400 kHz to about 10 mHz. Of course, other forms of energy can be applied, e.g., coherent or incoherent light; heated or cooled fluid; resistive heating; microwave; ultrasound; a tissue ablation fluid; or cryogenic fluid.

A selected device 26 a/26 b can be individually coupled to the generator 38 via a cable 10 to convey the generated energy to the respective operative element 36 a/36 b.

The system 24 preferably also includes certain auxiliary processing equipment. In the illustrated embodiment, the processing equipment comprises an external fluid delivery apparatus 44 and an external aspirating apparatus 46.

A selected device 26 a/26 b can be connected via tubing 12 to the fluid delivery apparatus 44, to convey processing fluid for discharge by or near the operative element 36 a/36 b. A selected device 26 a/26 b can also be connected via tubing 14 to the aspirating apparatus 46, to convey aspirated material from or near from the operative element 36 a/36 b for discharge.

The system 24 also includes a controller 52. The controller 52, which preferably includes a central processing unit (CPU), is linked to the generator 38, the fluid delivery apparatus 44, and the aspirating apparatus 46. Alternatively, the aspirating apparatus 46 can comprise a conventional vacuum source typically present in a physician's suite, which operates continuously, independent of the controller 52.

The controller 52 governs the power levels, cycles, and duration that the radio frequency energy is distributed to the particular operative element 36 a/36 b, to achieve and maintain power levels appropriate to achieve the desired treatment objectives. In tandem, the controller 52 also desirably governs the delivery of processing fluid and, if desired, the removal of aspirated material. Thus, the controller maintains the target tissue temperature to ensure the tissue is not overheated.

The controller 52 includes an input/output (I/O) device 54. The I/O device 54 allows the physician to input control and processing variables, to enable the controller to generate appropriate command signals. The I/O device 54 also receives real time processing feedback information from one or more sensors associated with the operative element (as will be described later), for processing by the controller 52, e.g., to govern the application of energy and the delivery of processing fluid.

The I/O device 54 also includes a graphical user interface (GUI), to graphically present processing information to the physician for viewing or analysis. Further details regarding the GUI will be provided later.

II. The Treatment Devices

The structure of the operative element 36 can vary. Various representative embodiments will be described.

A. For Treatment of Upper Gastro-Intestinal Tract

FIGS. 2 to 4 show a catheter-based device 26 a for treating sphincter regions in the upper gastro-intestinal tract, and more particularly, the lower esophageal sphincter and adjoining cardia of the stomach to treat GERD. In the embodiment shown, the device 26 a includes a flexible catheter tube 30 that carries a handle 28 at its proximal end. The distal end of the catheter tube 30 carries the operative element 36 a.

In the illustrated embodiment, the operative element 36 a comprises a three-dimensional basket 56. The basket 56 includes one or more spines 58, and typically includes from four to eight spines 58, which are assembled together by a distal hub 60 and a proximal base 62. In the illustrated embodiment, four spines 58 are shown, spaced circumferentially at 90-degree intervals.

In the illustrated embodiment, an expandable structure 72 comprising a balloon is located within the basket 56. The balloon structure 72 can be made, e.g., from a Polyethylene Terephthalate (PET) material, or a polyamide (non-compliant) material, or a radiation cross-linked polyethylene (semi-compliant) material, or a latex material, or a silicone material, or a C-Flex (highly compliant) material.

The balloon structure 72 presents a normally, generally collapsed condition, as FIG. 2 shows. In this condition, the basket 56 is also normally collapsed about the balloon structure 72, presenting a low profile for deployment into the esophagus.

A catheter tube 30 includes an interior lumen, which communicates with the interior of the balloon structure 72. A fitting 76 (e.g., a syringe-activated check valve) is carried by the handle 28. The fitting 76 communicates with the lumen. The fitting 76 couples the lumen to a syringe 78 (see FIG. 3). The syringe 78 injects fluid under pressure through the lumen into the balloon structure 72, causing its expansion.

Expansion of the balloon structure 72 urges the basket 56 to open and expand (see FIG. 3). The force exerted by the balloon structure 72, when expanded, is sufficient to exert an opening or dilating force upon the tissue surrounding the basket 56 (see FIG. 31). The balloon can be expanded to varying diameters to accommodate for varying patient anatomy.

Each spine 58 carries an electrode 66 (see FIG. 4). Therefore, there are four electrodes circumferentially spaced at 90-degree intervals. In the illustrated embodiment, each electrode 66 is carried within the tubular spine 58 for sliding movement. Each electrode 66 slides from a retracted position, withdrawn in the spine 58 (shown in FIG. 3) and an extended position, extending outward from the spine 58 (see FIG. 4) through a hole in the spine 58. A push-pull lever 68 on the handle 28 is coupled by one or more interior wires to the sliding electrodes 66. The lever 68 controls movement of the electrodes between the retracted position (by pulling rearward on the lever 68) and the extended position (by pushing forward on the lever 68).

The electrodes 66 have sufficient distal sharpness and strength, when extended, to penetrate a desired depth into tissue the smooth muscle of the lower esophageal sphincter 18 or the cardia of the stomach 16 (see FIG. 32). The desired depth can range from about 4 mm to about 5 mm.

The electrodes 66 are formed of material that conducts radio frequency energy, e.g., nickel titanium, stainless steel, e.g., 304 stainless steel, or a combination of nickel titanium and stainless steel.

In the illustrated embodiment (see FIG. 4), an electrical insulating material 70 is coated about the proximal end of each electrode 66. When the distal end of the electrode 66 penetrating the smooth muscle of the esophageal sphincter 18 or cardia 20 transmits radio frequency energy, the material 70 insulates the mucosal surface of the esophagus 10 or cardia 20 from direct exposure to the radio frequency energy. Thermal damage to the mucosal surface is thereby avoided. The mucosal surface can also be actively cooled during application of radio frequency energy, to further protect the mucosal surface from thermal damage.

In the illustrated embodiment (see FIG. 4), at least one temperature sensor 80 is associated with each electrode. One temperature sensor 80 senses temperature conditions near the exposed distal end of the electrode 66, a second temperature sensor 80 is located on the corresponding spine 58, which rests against the mucosal surface when the balloon structure 72 is inflated.

The external fluid delivery apparatus 44 is coupled via tubing 12 (see FIG. 1) to connector 48 (see FIG. 4), to supply cooling liquid to the targeted tissue, e.g., through holes in the spines. The external aspirating apparatus 46 is coupled via tubing 14 (see FIG. 1) to connector 50 (see FIG. 4), to convey liquid from the targeted tissue site, e.g., through other holes in the spine or elsewhere on the basket 56. The controller 52 can govern the delivery of processing fluid and, if desired, the removal of aspirated material.

The controller 52 can condition the electrodes 66 to operate in a monopolar mode. In this mode, each electrode 66 serves as a transmitter of energy, and an indifferent patch electrode (described later) serves as a common return for all electrodes 66. Alternatively, the controller 52 can condition the electrodes 66 to operate in a bipolar mode. In this mode, one of the electrodes comprises the transmitter and another electrode comprises the return for the transmitted energy. The bipolar electrode pairs can include electrodes 66 on adjacent spines, or electrodes 66 spaced more widely apart on different spines.

In use, the device 26 a is manipulated to create a preferred pattern of multiple lesions comprising circumferential rings of lesions at several axially spaced-apart levels (about 5 mm apart), each level comprising from 8 to 12 lesions. A representative embodiment of the lesion pattern is shown in FIG. 5. As FIG. 5 shows, the rings are preferably formed in the esophagus in regions above the stomach, at or near the lower esophageal spincter, and/or in the cardia of the stomach. The rings in the cardia are concentrically spaced about the opening funnel of the cardia. At or near the lower esophageal sphincter, the rings are axially spaced along the esophagus.

Multiple lesion patterns can be created by successive extension and retraction of the electrodes 66, accompanied by rotation and/or axial movement of the catheter tube to reposition the basket 56. The physician can create a given ring pattern by expanding the balloon structure 72 and extending the electrodes 66 at the targeted treatment site, to form a first set of four lesions. The physician can then withdraw the electrodes 66, collapse the balloon structure 72, and rotate the catheter tube 30 by a desired amount, e.g., 30-degrees or 45-degrees, depending upon the number of total lesions desired within 360-degrees. The physician can then again expand the structure 72 and again extend the electrodes 66, to achieve a second set of four lesions. The physician repeats this sequence until a desired number of lesions within the 360-degree extent of the ring is formed. Additional lesions can be created at different levels by advancing the operative element axially, gauging the ring separation by external markings on the catheter tube.

As shown in FIG. 5, a desirable pattern comprises an axially spaced pattern of six circumferential lesions numbered Level 1 to Level 6 in an inferior direction, with some layers in the cardia of the stomach, and others in the esophagus above the stomach at or near the lower esophageal sphincter. In the embodiment shown in instant FIG. 5, in the Levels 1, 2, 3, and 4, there are eight lesions circumferentially spaced 45-degrees apart (i.e., a first application of energy, followed by a 45-degree rotation of the basket 56, followed by a second application of energy). In the Levels 5 and 6, there are twelve lesions circumferentially spaced 30-degrees apart (i.e., a first application of energy, followed by a 30-degree rotation of the basket 56, followed by a second application of energy, followed by a 30-degree rotation of the basket 56, followed by a third application of energy). In Level 5, the balloon structure 72 is only partially expanded, whereas in Level 6, the balloon structure 72 is more fully expanded, to provide lesion patterns that increase in circumference according to the funnel-shaped space available in the funnel of the cardia.

Note that to secure against overinflation of the balloon, especially in tissue Levels 1-4 where the device is positioned in the esophagus, a pressure relief valve is attached to the air syringe, upstream of the balloon inflation port of the device, to allow air to escape if pressure levels are exceeded. That is, in Levels 1-4, the air syringe is filled with air, and the balloon is inflated to a target pressure so there is enough contact to slightly tension the tissue but not enough to stretch the tissue, with the pressure relief ensuring the pressure is not exceeded. Preferably, the balloon would be inflated to no more than about 2.5 psi. In the stomach, at Levels 5 and 6, there is more room for the balloon inflation, so the balloon can be further inflated and the pressure relief valve can be removed. The balloon is preferably inflated by volume to about 25 ml for treatment at Level 5, and after treatment at Level 5, deflated at Level 6 to about 22 ml. Note at Levels 5 and/or 6, the inflated balloon can also be used as an anchor. In an alternate embodiment, after treatment of Level 4 the balloon is deflated and the instrument is advanced, then retracted, wherein Level 6 is treated, then the instrument is pulled further proximally to subsequently treat Level 5. Stated another way, Level 5 can be considered distal of Level 6 and therefore being more distal, treated before Level 6. Note the balloon would still be inflated to about 25 ml in the more distal level and to about 22 ml in this embodiment. The balloon can also serve as an anchor.

In an alternate embodiment of the treatment device 26 a, one or more digital cameras can be mounted along the catheter tube, e.g., with the camera lens directed to the basket 56, to provide visualization of the site. In another alternate embodiment, the catheter tube can be designed to fit within a lumen of an endoscope, relying on the endoscope for visualization of the site.

B. For Treatment of Lower Gastro-Intestinal Tract

FIGS. 6 and 7 show a representative embodiment for device 26 b, which takes the form of a hand manipulated device 302 for treating sphincter regions in the lower gastro-intestinal tract, and more particularly, the internal and/or external sphincter muscles in the anal canal to treat fecal incontinence. The device 302 includes a hand grip 304 that carries the operative element 36 b.

In the illustrated embodiment, the operative element 36 b takes the form of a hollow, tubular barrel 306 made from a transparent, molded plastic material. The barrel 306 terminates with a blunt, rounded distal end 308 to aid passage of the barrel 306 through the anal canal, without need for a separate introducer. The hand grip 304 includes a viewing port 312 for looking into the transparent, hollow interior of the barrel 306, to visualize surrounding tissue.

An array of needle electrodes 316 are movably contained in a side-by-side relationship along an arcuate segment of the barrel 306. In the illustrated embodiment, the needle electrodes 316 occupy an arc of about 67.5 degrees on the barrel 306. The needle electrodes 316 are mechanically linked to a finger-operated pull lever 318 on the hand grip 304. By operation of the pull lever 318, the distal ends of the needle electrodes 316 are moved between a retracted position (FIG. 5) and an extended position (FIG. 6 of the '523 patent). An electrical insulating material 344 is coated about the needle electrodes 316 (see FIG. 6 of the '523 patent), except for a prescribed region of the distal ends, where radio frequency energy is applied to tissue. The generator 38 is coupled via the cable 10 to a connector 352, to convey radio frequency energy to the electrodes 316.

In use (see FIG. 8), the physician grasps the hand grip 304 and guides the barrel 306 into the anal canal 320. The pull lever 318 is in the neutral position and not depressed, so the needle electrodes 316 occupy their normal retracted position. Looking through the viewing port 312, the physician visualizes the pectinate (dentate) line through the barrel 306. Looking through the barrel 306, the physician positions the distal ends of the needle electrodes 316 at a desired location relative to the pectinate (dentate) line. A fiberoptic can also be located in the barrel 306 to provide local illumination. Once the distal end of the barrel 306 is located at the targeted site, the physician depresses the pull lever 318 (as FIG. 8 shows). The needle electrodes 316 advance to their extended positions. The distal ends of the electrodes 316 pierce and pass through the mucosal tissue into the muscle tissue of the target sphincter muscle. In FIG. 8, the distal end of the electrodes 316 are shown penetrating the involuntary, internal sphincter muscle 322. The physician commands the controller 52 to apply radio frequency energy through the needle electrodes 316. The energy can be applied simultaneously by all electrodes 316, or in any desired sequence.

The external fluid delivery apparatus 44 is coupled via tubing 12 to a connector 348 to convey a cooling liquid, e.g., through holes in the barrel 306, to contact tissue at a localized position surrounding the electrodes 316. The external aspirating apparatus 46 is coupled via tubing 14 to a connector 350 to convey liquid from the targeted tissue site, e.g., through an aspiration port 358 in the distal end 308 of the barrel 306 (see FIGS. 6 and 7).

The barrel 306 (see FIG. 7) also preferably carries temperature sensor 364, one of which is associated with each needle electrode 316. The sensors 364 sense tissue temperature conditions in the region adjacent to each needle electrode 316. Preferably, the distal end of each needle electrode 316 also carries a temperature sensor 372 (see FIG. 7).

In use (see FIG. 9), a preferred pattern of multiple lesions is formed comprising several circumferential rings of lesions in axially spaced-apart levels (about 5 mm apart), each ring comprising 16 lesions in four quadrants of 4 each. The rings are formed axially along the anal canal, at or near the dentate line.

The fluid delivery apparatus 68 conveys cooling fluid for discharge at the treatment site, to cool the mucosal surface while energy is being applied by the needle electrodes 316. The aspirating apparatus 76 draws aspirated material and the processing fluid through the tubing 78 for discharge.

Referring to FIG. 9, the array of needle electrodes 316 is positioned at Level 1 to create four multiple lesions in the first quadrant. Upon the satisfactory creation of the lesion pattern in the first quadrant of Level 1, as just described, the physician actuates the button 64 to release the locking pawl 58 from the detent 62. The pull lever 318 returns to the spring-biased neutral position, thereby moving the needle electrodes 316 back to their retracted positions. Still grasping the hand grip 304 and visualizing through the viewing port 312, the physician moves the barrel 5 mm axially upward to Level 2, the first quadrant. The physician again deploys the needle electrodes 316 and performs another lesion generating sequence. The physician repeats this sequence of steps until additional number of lesion patterns are formed within the axially spaced first quadrants in Levels 1, 2, 3, 4, and 5.

Still grasping the hand grip 304 and visualizing through the viewing port 312, the physician returns to level 1, and rotates the barrel 306 a selected arcuate distance at the level of the first lesion pattern 94 to the second quadrant, i.e., by rotating the barrel 306 by ninety degrees.

The physician again deploys the needle electrodes 316 and performs another lesion generating sequence at quadrant 2 of Level 1. The physician then moves the barrel axially upward in 5 mm increments, at a number of axially spaced levels 2, 3, 4, and 5 generally aligned with lesion patterns 96, 98, and 100. Lesions are formed in this way in the second quadrant of Levels 1, 2, 3, 4, and 5.

The physician repeats the above described sequence two additional times, returning the barrel to level 1 and rotating the barrel 306 at successive intervals and axially repositioning the barrel 306 to form the lesion patterns quadrants 3 and 4 in the Levels 1, 2, 3, 4, and 5. This protocol forms a composite lesion pattern 102, which provides a density of lesions in the targeted sphincter tissue region to provoke a desired contraction of the sphincter tissue.

III. System Operation

In the illustrated embodiment (see FIGS. 10A and 10B), the radio frequency generator 38, the controller 52 with I/O device 54, and the fluid delivery apparatus 44 (e.g., for the delivery of cooling liquid) are integrated within a single housing 400.

The I/O device 54 couples the controller 52 to a display microprocessor 474 (see FIG. 10A). The display microprocessor 474 is coupled to a graphics display monitor 420 in the housing 400. The controller 52 implements through the display microprocessor 474 the graphical user interface, or GUI, which is displayed on the display monitor 420. The graphical user interface can be realized with conventional graphics software using the MS WINDOWS® application. The GUI is implemented by showing on the monitor 420 basic screen displays.

A. Set-Up

Upon boot-up of the CPU (see FIG. 11), the operating system implements the SET-UP function for the GUI 500. The GUI displays an appropriate start-up logo and title image (not shown), while the controller 52 performs a self-test. An array of SETUP prompts 502 leads the operator in a step-wise fashion through the tasks required to enable use of the generator and device. The physician can couple the source of cooling liquid to the appropriate port on the handle of the device 26 a/26 b (see FIG. 10A, as previously described) and load the tubing leading from the source of cooling liquid (e.g., a bag containing sterile water) into the pump rotor 428 (see FIG. 10B). The physician can also couple the aspiration source 46 to the appropriate port on the handle of the treatment device 26 a/26 b (as also already described). The physician can also couple the patch electrode 412 and foot pedal 416 (shown in FIG. 10A). In the SET-UP prompt array 502, a graphic field of the GUI 500 displays one or more icons and/or alpha-numeric indicia 502 that prompt the operator to connect the return patch electrode 412, connect the foot pedal or switch 416, connect the selected treatment device 26 a (designed by its trademark STRETTA®) or 26 b (designated by its trademark SECCA®), and to prime the irrigation pump 44.

Note in some embodiments, the user controls the pump speed to increase fluid flow if the temperature is rising. In alternate embodiments, the system is designed with an automatic cooling feature, thus enabling quicker application of cooling fluid to address rising tissue temperatures to faster cool the tissue surface which in turn cools the underlying tissue which helps to maintain the tissue temperature below the “tissue ablation threshold.”

More specifically, at certain tissue temperatures, the speed of the pump is changed automatically to reduce the temperature. That is, if the tissue surface temperature, e.g., at the mucosa layer as measured by the tissue temperature sensor, reaches a certain threshold (a “first value”), the pump speed will increase to pump more cooling fluid to the tissue. In some embodiments, for certain tissue temperature values, the system can enable the user to override the automatic pump to reduce the fluid flow. In other embodiments, a user override feature is not provided. In either case, the system is preferably designed so that if a second predetermined higher temperature value (“second value”) is reached, the pump is automatically moved to its maximum pump speed, which preferably cannot be overridden by the user. When a third predetermined still higher tissue temperature value is reached (a “third cutoff value”), the electrode channel is disabled as discussed herein to shut off energy flow to that electrode. Consequently, before the third cut off value is reached, as the temperature is rising, the system provides for a quicker response to the rising temperature by automatically increasing fluid flow, rather than relying on the slower response time of the user to implement the pump speed change, thereby helping to keep temperature below the tissue ablation threshold temperature.

Exemplary tissue values are provided solely by way of example, it being understood that other tissue values can also be utilized to achieve quick application of cooling fluid and ensure the non-ablation, and non-burning, of tissue. For example, in the upper GI tract treatment device described herein (see FIG. 3), the first value could be about 38 degrees, the second predetermined value could be about 40 degrees and the third value where the energy is shut down could be about 43 degrees. For a lower GI tract treatment device described herein (see FIG. 6), the first value could be about 45 degrees, the second predetermined value could be about 46 degrees and the third value where the energy is shut down could be about 54 degrees.

The controller 52 ascertains which device 26 a or 26 b has been selected for use by reading a coded identification component residing in the handle of the device 26 a or 26 b. Based upon this input, the controller 52 proceeds to execute the preprogrammed control and graphical GUI command functions for the particular device 26 a and 26 b that is coupled to the generator.

If the identification code for the device 26 a, (STRETTA®) is registered, the GUI displays an appropriate start-up logo and title image for the device 26 a (see FIG. 12). Likewise, if the identification code for the device 26 b (SECCA®) is registered, the GUI displays an appropriate start-up logo and title image for the device 26 b (FIG. 13).

In some embodiments, the coded identification device is part of a printed circuit board (PCB) positioned in the handle of the treatment device. The PCB for each device is illustrated generally in FIGS. 2A and 6A, and designated by reference numerals 29, 329, respectively, and processes the calculated parameters. The PCB in conjunction with thermocouples provides a temperature measurement mechanism. The PCB measures the voltage generated by the thermocouples, converts it from an analog to a digital value and stores it in the internal memory. Upon request by the generator, the PCB communicates the digital data to the generator. This step is performed during the 100 millisecond break between radiofrequency pulses discussed below. By placement of the temperature measurement mechanism in the treatment device, i.e., in the disposable handpiece, rather than in the housing 400, data collection is closer to the source which translates into less noise susceptibility and improved accuracy. That is, since processing of temperature values occurs closer to the tissue and electrode tip, measurements can be more accurate. More accurate readings translate into tighter power controls and better clinical results and it better ensures the tissue is not ablated during treatment as it is maintained below a tissue ablation threshold.

In a preferred embodiment, the PCB, which is asymmetrically positioned within the handle, is shielded to reduce interference which could otherwise disrupt communication between the disposable treatment device and the generator. Such interference (noise) could corrupt the data and unnecessarily result in system errors which can unnecessarily shut down energy flow to the electrode(s) during the procedure. In a preferred embodiment, the shield is a copper foil, although other ways to shield the PCB are also contemplated. In other words, the disruption of communication could adversely affect processing and evaluation of the data collected by the treatment device. By eliminating such disruptions, and thereby disabling fewer electrodes improved consistency of treatment is achieved. Also, as can be appreciated, if too many electrodes are disabled in a procedure, the tissue may not be sufficiently thermally treated to achieve the desired clinical result.

In an alternate embodiment of the treatment devices shown in FIGS. 2B and 6B, the identification code is positioned in the handle of the treatment device 26 a, 26 b, generally designated by reference numerals 29 a, 329 a, respectively, but the other hardware, e.g., the printed circuit board for temperature calculation, etc. is outside the handle and represented generally by reference numeral 49 in FIG. 2B and reference numeral 340 in FIG. 6B. Thus, the temperature data collection is performed outside the disposable treatment device which reduces costs since it need not be disposed of with the disposable treatment device. Note the embodiments of FIGS. 2B and 6B still have the advantage of data collection closer to the source than if in the housing 400.

B. Treatment Screens (UGUI and LGUI)

Upon completion of the SET-UP operation, the controller 52 proceeds to condition the generator and ancillary equipment to proceed step-wise through a sequence of operational modes. The operational modes have been preprogrammed to achieve the treatment protocol and objective of the selected device 26 a/26 b. The conduct of these operational modes and the appearance of the graphical user interface that guides and informs the user during the course of the selected procedure can differ between devices 26 a and 26 b.

For ease of description, the GUI 500 displays for the upper gastro-intestinal procedure (i.e., for the device 26 a) a treatment screen that will in shorthand be generally called UGUI 504 (FIG. 14A). Likewise, the GUI displays for the lower gastro-intestinal procedure (i.e., for the device 26 b) a treatment screen that will in shorthand be generally called LGUI 506 (FIG. 15A).

In both the UGUI 504 (FIG. 14A) and LGUI 506 (FIG. 15A), there is a parameter icon 462 designating cooling fluid flow rate/priming. In both the UGUI 504 and the LGUI 506, the Flow Rate/Priming Icon 462 shows the selected pump speed by the number of bars, one bar highlighting a low speed, two bars highlighting a medium speed, and three bars highlighting a high speed.

Each UGUI 504 (FIG. 14A) and LGUI 506 (15A) includes an Electrode Icon 466. In general, each Electrode Icon 466 comprises an idealized graphical image, which spatially models the particular multiple electrode geometry of the treatment device 26 a/26 b that has been coupled to the controller 42. Just as the multiple electrode geometries of the devices 26 a and 26 b differ, so, too, does the Electrode Icon 466 of the UGUI 504 differ from the Electrode Icon 466 of the LGUI 506.

As FIG. 14A shows, in the UGUI 504, four electrodes are shown in the graphic image of the Icon 466, which are spaced apart by 90 degrees. This graphic image reflects the geometry of the four-electrode configuration of the device 26 a, as shown in FIG. 4.

As FIG. 15A shows, in the LGUI 506, four electrodes are shown in the graphic image of Icon 466 in a circumferentially spaced relationship along a partial arcuate sector. This graphic image reflects the arrangement of electrodes on the treatment device 26 b, as shown in FIG. 7.

For each electrode, the respective Icon 466 incorporates graphic regions O1, O2, and O3 in the spatial display. Regions O1 and O2 display temperature conditions encountered for that electrode. Region O1 numerically displays the magnitude of sensed electrode tip temperature in UGUI 504 (FIG. 14A) and LGUI 506 (FIG. 15A). Region O2 numerically displays sensed tissue temperatures for that electrode in UGUI 504 (FIG. 14A) and LGUI 506 (FIG. 15A). Region O3 displays the derived impedance value for each electrode. Both UGUI 504 and LGUI 506 display instantaneous, sensed temperature readings from the tip electrode and tissue surface, as well as impedance values, which are continuously displayed in spatial relation to the electrodes in the regions O1, O2, and O3.

The numeric displays of the regions O1/O2/O3 can be blanked out for a given electrode if the corresponding electrode/channel has been disabled, either by the physician or by a sensed out-of-bounds condition. An “acceptable” color indicator (e.g., green) can also be displayed in the background of the regions O1/O2/O3 as long as the sensed condition is within the desired pre-established ranges. However, if the sensed conditions fall outside the desired range, the color indicator changes to an “undesirable” color indicator (e.g., to grey), and numeric display is blanked out.

In a preferred embodiment, if an electrode/channel is disabled and the energy is turned off for that electrode, the corresponding icon is grayed out, but the numeric value remains on the screen, thus providing useful information to the user. Thus, at the end of the surgical procedure, the reasons for the shut down of the particular electrode can be evaluated so the user can learn what if any user errors occurred.

In some embodiments, temperature of the needle tips is measured when the needles are deployed at the lesion level, but prior to application of RF energy. If the measured temperature exceeds an expected value, the temperature reading alerts the user that the needle position might need to be readjusted. If the temperature value is too high, this can mean that the electrode position is too close to the previous tissue level treated, and thereby the user can readjust the electrode position by increasing the spacing, thereby reducing the chances of overtreating the tissue which can cause undesired tissue ablation or burning of tissue. Consequently, continuous treatment of tissue can be achieved with reduced overlapping of treatment.

Also, as can be appreciated, the temperature of the electrode tip, the tissue temperature and the impedance, along with other safety parameters, such as adequate connections, are monitored during the procedure to ensure energy flow is correct. This includes proper flow through the cable, electrodes, ground pad, etc. The electrode needle is then disabled if a safety condition is suspected and indicated. Each needle can be controlled separately.

In use of the system, impedance is intermittently checked throughout the procedure. Impedance is measured by measuring the current at the channel of the electrode tip. The impedance monitoring provides an indication of how well the treatment device is connected and communicating with the tissue, which includes the needle penetration and the path with the return pad. If there is not good contact between the electrode and tissue, impedance is high and a patient can get burned. Therefore, if a patient moves, needle penetration could be affected. However, oftentimes a minor adjustment can be made which does not require shutting down energy flow. To avoid premature shutting down of the system a multiple error check is conducted by the system which is described in more detail below. This multiple error check reduces the incidence of needle disabling which in turn reduces the incidence of undertreatment.

Note the impedance is measured by applying a voltage, measuring the current and calculating the impedance. The RF energy is applied in 0.9 second intervals, with a 0.1 second break in between where an artificial pulse is sent for 0.1 second, in which impedance is measured. The temperature of the electrode tip and tissue temperature is also measured during this 0.1 second interval, for calculating such measurement. Preferably, the RF energy is repeatedly applied for 0.9 seconds, with 0.1 second “measurement intervals” for a time period of 60 seconds.

There is also a Lesion Level Icon 510 in each display UGUI 504 and LGUI 506, adjacent to the respective Electrode Icon 466. The Lesion Level Icon 510 comprises an idealized graphical image, which spatially models the desired lesion levels and the number of lesions in each level. Just as the lesion patterns created by the devices 26 a and 26 b differ, so, too, does the Lesion Level Icon 510 of the UGUI 504 differ from the Electrode Icon 466 of the LGUI 506.

As will be described in greater detail later, the Lesion Level Icons 510 change in real time, to step-wise guide the physician through the procedure and to record the progress of the procedure from start to finish. In many fundamental respects, the look and feel of the Lesion Level Icons 510 for the LGUI 504 and the LGUI 506 are similar, but they do differ in implantation details, due to the difference of the protocols of lesion formation.

Exemplary changes in the Lesion Level Icons 510 for the UGUI 504 and the LGUI 506 will now be described.

1. The UGUI

In the UGUI 504 (se FIG. 14A), six numbered Lesion Levels 1, 2, 3, 4, 5, and 6 are displayed, to correspond with the lesion levels already described and shown in FIG. 5. The UGUI 504 also displays a squiggle line 514, which marks where the physician has visualized a selected anatomic home base reference for the formation of lesions within the esophagus for treatment. Guided by the UGUI 504, lesions are placed relative to this anatomic home base.

In preparation for the treatment, the physician visualizes in the esophagus the Z-line or other desired anatomic landmark. Markers are arranged at 5 mm intervals along the catheter tube. Upon visualizing the Z-line, the physician notes the external marker on the catheter tube that corresponds to this position. With reference to the markers, the physician can then axially advance or retract the catheter tube in 5 mm increments, which correspond to the desired spacing between the lesion levels. This orientation of lesion levels is also shown in FIG. 5.

The UGUI 504 graphically orients the location of Lesion Levels 4, 5, and 6 relative to this anatomical base, displaying Lesion Levels either below (inferior to) the squiggle line 514 (Lesion Levels 4, 5, and 6) or at or above the squiggle line 514 (Lesion Levels 1, 2, and 3).

As will be described, the UGUI 504 graphically changes the display of the Lesion Levels, depending upon the status of lesion formation within the respective levels.

FIG. 14A shows a representative first graphical form of a given lesion level. The graphical form comprises, e.g., a cylinder that faces edgewise on the UGUI 504, as is shown for Lesion Levels 1 to 6 in FIG. 14A. This graphical form indicates at a glance that no lesions are present in the respective lesion levels.

As is shown in FIG. 14A, next to the graphical form of the edgewise cylinder of Lesion Level 1 is a Guide Marker 512. The Guide Marker 512 indicates that formation of lesions in Lesion Level 1 is the first to be indicated. A numeric value (15 mm) is displayed in association with the edgewise cylinder of Lesion Level 1, which indicates that Lesion Level 1 is 15 mm from the anatomic landmark. The orientation of Lesion Level 1 above (superior to) the squiggle line 514 guides the physical to advance the catheter tube upward from the anatomic marker by 15 mm, to place it at Lesion Level 1. A Balloon Icon 516 prompts the physician to expand the basket of the device 26 a at Lesion Level 1.

Upon sensing electrode impedance, indicating contact with tissue at Lesion Level 1 (or in response to another input indicating deployment of the device 26 a at the desired lesion level), the controller commands the UGUI 504 to change the graphical form of Lesion Level 1 to a second graphical form, which is shown in FIG. 14B. The second graphical form (shown in FIG. 14B) is different than the first graphical form (shown in FIG. 14A). The graphical form comprises, e.g., a segmented circle, with a numeric indicator next to it. This is shown for Lesion Level 1 in FIG. 14B. In visual effect, the second graphical form shows the previously cylinder form rotated for viewing along its axis. The number of segments shown (in FIG. 14B, there are eight segments) corresponds with the number of lesions that are to be formed at Lesion Level 1.

In FIG. 14B, all segments of the circle are unmarked. This graphical form indicates at a glance that (i) formation of lesions at this lesion level is now indicated (due to the axial circle view of the lesion level icon), (ii) eight circumferentially spaced lesions are to be formed (due to the number of segments); (iii) no lesions have as yet been formed (by the lack of other markings in the segments).

The location of the Marker 512 also changes to align with Lesion Level 2, with a numeric indicator of 5 mm. This informs the physician that, after Lesion Level 1, the next lesion level to be treated is Lesion Level 2, which is 5 mm below (inferior to) Lesion Level 1.

With the device 26 a positioned at Lesion Level 1, the physician actuates the electrodes for a first pre-set period. The balloon icon 516 disappears as treatment progresses on a given level. A Timer Icon 518 shows the application of radio frequency energy for the pre-set period. At the end of this pre-set period (see FIG. 14C), treatment indicia (e.g., dots) appear in four segments of the graphical segmented circle, indicating the formation of the first four lesions, as well as their spatial orientation.

The open segments remaining in the segmented circle prompt the physician to rotate the basket by 45-degrees, and actuate the electrodes for second time. After the pre-set period (tracked by the Timer Icon 518) (see FIG. 14D), more treatment indicia (the dots) appear in the remaining segments of the circle. This indicates that all the lesions prescribed for Lesion Level 1 have been formed, and to deflate the basket and move to the next treatment level. The Marker 512 that is displayed directs the physician to Lesion Level 2, which is 5 mm below Lesion Level 1. The Balloon Icon 516 can reappear to prompt the physician to deflate the balloon.

The physician is thereby prompted to deflate the basket, move to Lesion Level 2, and expand the basket. As FIG. 14E shows, upon sensing electrode impedance, indicating contact with tissue at Lesion Level 2, the UGUI 504 changes the graphical form of Lesion Level 1 back to an edgewise cylinder. The edgewise cylinder for Lesion Level 1 includes an indicator, e.g., checkmark, to indicate that Lesion Level 1 has been treated (as shown in FIG. 14E). The insertion of the treatment completed indicator is yet another graphical form the UGUI 504 displays to communicate status information to the physician.

Also referring to FIG. 14E, upon sensing electrode impedance, indicating contact with tissue at Lesion Level 2, the UGUI 504 changes the graphical form of Lesion Level 2 to the second graphical form, comprising, e.g., the segmented circle, as already described. This is shown for Lesion Level 2 in FIG. 14E. The location of the Marker 512 also changes to align with Lesion Level 3, with a numeric indicator of 5 mm. This informs the physician that after Lesion 2, the next lesion level will be Lesion Level 3, which is 5 mm below (inferior to) Lesion Level 2.

As shown in FIGS. 14F and 14G, with the device 26 a positioned at Lesion Level 2, the physician actuates the electrodes for a first pre-set period, then rotates the device 26 a 45-degrees, and actuates the electrodes for the second pre-set period. The Timer Icon 518 reflects the application of radio frequency energy for the pre-set periods, and the treatment indicia (e.g., dots) are added to the segments of the graphical segmented circle, indicating the formation of the first four lesions (FIG. 14F) and the next four lesions (FIG. 14G), as well as their spatial orientation.

Upon formation of the eight lesions in Lesion Level 2, the balloon icon 518 again appears. This indicates that all the lesions prescribed for Lesion Level 2 have been formed, and to deflate the basket and move to the next treatment level. The Marker 512 that is displayed directs the physician to Lesion Level 3, which is 5 mm below Lesion Level 2.

The physician is thereby prompted to deflate the basket, move to Lesion Level 3, and expand the basket. Upon sensing electrode impedance, indicating contact with tissue at Lesion Level 3 (see FIG. 14H), the UGUI 504 changes the graphical form of Lesion Level 2 back to an edgewise cylinder (as FIG. 14H shows). The edgewise cylinder for Lesion Level 2 now includes an indicator, e.g., the checkmark, to indicate that Lesion Level 2 has been treated (as FIG. 14H also shows).

As FIG. 14I also shows, upon sensing electrode impedance, indicating contact with tissue at Lesion Level 3, the UGUI 504 changes the graphical form of Lesion Level 3 to the second graphical form, comprising, e.g., the segmented circle, as already described. This is shown for Lesion Level 3 in FIG. 14H. The location of the Marker 512 also changes to align with Lesion Level 4, with a numeric indicator of 5 mm. This informs the physician that after Lesion 3, the next lesion level will be Lesion Level 3, which is 5 mm below (inferior to) Lesion Level 3.

The physician proceeds to form eight lesions in Lesion Level 3 (FIGS. 14I and 14J), then moving on to Lesion Level 4 (not shown, but following the same progression as already described). All the while, the UGUI 504 visually records and confirms progress. As shown in FIG. 14K, the graphical Lesion Level cylinders for Lesion Levels 3 and 4 return edgewise when the desired number of lesions has been formed on the respective level and treatment at the level has been completed. At that time, a check mark appears on the edgewise cylinder, indicating that treatment at that level has been completed for Lesion Levels 1, 2, 3, and 4 (as shown in FIG. 14K).

In FIGS. 14K to 14N, on Lesion Levels 5 and 6, the segments in the segmented circle number twelve, indicating that twelve lesions are to be formed on these levels. In the Levels 5 and 6, there are twelve lesions circumferentially spaced 30-degrees apart (i.e., a first application of energy, followed by a 30-degree rotation of the basket 56, followed by a second application of energy, followed by a 30-degree rotation of the basket 56, followed by a third application of energy). In Level 5, the balloon structure is only partially expanded, whereas in Level 6, the balloon structure 72 is more fully expanded, to provide lesion patterns that increase in circumference according to the funnel-shaped space available in the funnel of the cardia.

The UGUI 504 reflects completion of the treatment (see FIG. 140).

In preferred embodiments, a series of icons related to balloon inflation are displayed on the graphical user interface. More specifically, as soon as the system is ready to begin treatment, a pressure relief valve icon as depicted in FIG. 14P appears on the treatment screen (see also FIG. 14Q). This icon 550 serves as a reminder to the user to utilize the relief valve, as described above, to prevent overinflation of the balloon at Lesion Levels 1-4. As soon as the treatment cycle begins, the relief valve icon 550 disappears from the screen. After treatment at Lesion Levels 1-4, before treatment at Level 5 begins, balloon icon 552, which has a 25 ml label, appears to indicate inflation of the balloon to 25 ml. Icon 552 disappears when treatment at Level 5 begins. Before treatment at Level 6, balloon icon 554 with a 22 ml label to remind the user to deflate the balloon to 22 ml appears. Balloon icon 554 disappears from the screen when treatment at Level 6 begins.

Thus, the UGUI 504, by purposeful manipulation of different stylized graphical images, visually prompts the physician step wise to perform a process of forming a pattern of lesions comprising a plurality of axially spaced lesion levels, each lesion level comprising a plurality of circumferential spaced lesions. The UGUI 504 registers the formation of lesions as they are generated in real time, both within and between each circumferentially spaced level. The UGUI 504 therefore displays for the physician a visual record of the progress of the process from start to finish. The UGUI 504 assures that individual lesions desired within a given level are not skipped, or that a given level of lesions is not skipped.

In the UGUI 508, each Lesion Level 1 to 6 is initially depicted by a first stylized graphical image comprising an edgewise cylinder with a number identification of its level. When the formation of lesions at a given level is indicated, the UGUI 504 changes the first stylized graphical image into a second stylized graphical image, different than the first image, comprising an axial view of the cylinder, presented as a segmented circle, with the numbers of segments corresponding to the number of lesions to be formed. There also appears juxtaposed with the next lesion level to be treated (still displayed as an edgewise cylinder), a marker along with a number indicating its distance from the present legion level. As the physician manipulates the device 26 a to form lesions on the indicated levels, the second graphical image further changes to a third graphical image, different than the first or second images, by adding indicia within the segmented circle to reflect the formation of lesions, to guide the physician to successively rotate and operate the device 26 a at the lesion level. Upon forming the desired lesion pattern on a given level, the UGUI 504 again changes the third graphical image to a fourth graphical image, different than the first, second, and third graphical images, comprising an edgewise cylinder with a number identification of its level, and further an indicator (e.g. a check mark) that indicates all desired lesions have been formed at the respective level. A Marker 512 is successively updated to direct the physician to the next Lesion Level. In this way, the UGUI 504 prompts the formation of eight lesions circumferentially spaced 45-degrees apart in the Levels 1, 2, 3, and 4, and the formation of twelve lesions circumferentially spaced 30-degrees apart at Lesion Levels 5 and 6. Thus, a total of 56 lesions can be formed in this procedure.

2. The LGUI

The LGUI 506 (FIG. 15A) generates a graphical user display that guides the physician in manipulating the device 26 b to form a prescribed lesion pattern in the anal canal, as shown in FIG. 9. The lesion pattern comprises a plurality of axially spaced lesion levels (in the illustrated embodiment, numbered 1 to 5), each lesion level comprising a plurality of circumferential spaced lesions (In the illustrated embodiment, there are sixteen lesions, arranged in sets of four).

The display of the LGUI 506 (see FIG. 15A) shows Lesion Levels 1, 2, 3, 4, and 5, corresponding with the multiple lesion levels to be formed in the anal canal. Lesion Levels 1 to 5 are displayed as segmented discs, numbered 1 to 5, which are tilted slightly on their axes, and arranged one above the other. Each disc is divided into four quadrants.

The LGUI 506 also shows (see FIG. 15A) a dentate squiggle line 514. In preparation for the treatment, the physician visualizes in the anal canal dentate line or other desired anatomic landmark. Markers are arranged at 5 mm intervals along the barrel of the device 26 b. Upon visualizing the dentate line, the physician notes the external marker on the barrel that corresponds to this position. With reference to the markers, the physician can then axially advance or retract the barrel in 5 mm increments, which correspond to the spacing between the lesion levels.

Next to the graphical form of the disc of Lesion Level 1 is a Guide Marker 512 (see FIG. 15A). The Guide Marker 512 indicates that formation of lesions in Lesion Level 1 is indicated. A numeric value (5 mm) is displayed in association with the edgewise cylinder of Lesion Level 1, which indicates that Lesion Level 1 is 5 mm from the anatomic landmark.

In FIG. 15A, all quadrants of the lesion level discs are unmarked. This graphical form indicates at a glance that (i) formation of lesions at Lesion Level 1 is now indicated (due to the position of the Marker 512) and (ii) no lesions have as yet been formed (by the lack of markings in the quadrants).

The device 26 b includes an array of four needle electrodes arranged in an arc, which can be advanced and retracted (see FIG. 6). The array of needle electrodes is positioned at Level 1, in alignment with quadrant 1, and advanced. The physician actuates the electrodes for a first pre-set period. A Timer Icon 518 shows the application of radio frequency energy for the pre-set period. At the end of this pre-set period, treatment indicia (e.g., four dots) appear in the first quadrant of the graphical segmented discs (see FIG. 15B), indicating the formation of the first four lesions, as well as their spatial orientation in the first quadrant.

The location of the Marker 512 also changes to align with Lesion Level 2, with a numeric indicator of 5 mm. This informs the physician that after Lesion Level 1, the next lesion level will be Lesion Level 2, which is 5 mm above (superior to) Lesion Level 1.

Upon the satisfactory creation of the lesion pattern in the first quadrant of Level 1, as just described, and as prompted by the Marker 512 (now aligned with Lesion Level 2), the physician actuates the button to move the needle electrodes back to their retracted positions Still grasping the hand grip and visualizing through the viewing port, the physician moves the barrel 5 mm axially upward to Level 2, remaining rotationally aligned in the first quadrant. The physician again deploys the needle electrodes and performs another lesion generating sequence. The location of the Marker 512 also changes to align with Lesion Level 3, with a numeric indicator of 5 mm. This informs the physician that after Lesion Level 2, the next lesion level will be Lesion Level 3, which is 5 mm above (superior to) Lesion Level 2. Treatment indicia (e.g., four dots) appear in the first quadrant of the graphical segmented disc of Lesion Level 2 (see FIG. 15C), indicating the formation of the four lesions, as well as their spatial orientation in the first quadrant.

The physician repeats this sequence of steps until additional number of lesion patterns are formed within the axially spaced first quadrants in Levels 2, 3, 4, and (see FIGS. 15D, 15E, and 15F). The location of the Marker 512 also changes to align with successive Lesion Levels, to guide the physician through the lesion levels. Treatment indicia (e.g., four dots) appear in the first quadrant of the graphical segmented discs of Lesion Levels 2, 3, 4, and 5 (see FIG. 15F), indicating the formation of the four lesions, as well as their spatial orientation in the first quadrant.

Upon formation of the four lesions in quadrant 1 of Lesion Level 5, the Marker 512 returns to Lesion Level 1 (see FIG. 15F), prompting the physician to return to Lesion Level 1, and again rotate the barrel a selected arcuate distance at Lesion Level 1 into alignment with the second quadrant, i.e., by rotating the barrel by ninety degrees.

Guided by the LGUI 506, the physician again deploys the needle electrodes and performs another lesion generating sequence at quadrant 2 of Level 1. Guided by the LGUI 506 (as shown in FIG. 15G), and following the Marker 512, the physician then moves the barrel axially upward in 5 mm increments, sequentially to quadrant 2 of Lesion Level 2, then quadrant 2 of Lesion Level 3, then quadrant 2 of Lesion Level 4, and quadrant 2 of Lesion Level 5. At each Lesion Level, the physician deploys the needle electrodes and performs another lesion generating sequence at quadrant 2 of the respective level. After lesion formation at each Lesion Level, treatment indicia (e.g., four dots) appear in the second quadrant of the graphical segmented discs of Lesion Levels 2, 3, 4, and 5 (see FIG. 15G), indicating the formation of the four lesions, as well as their spatial orientation in the second quadrant.

Upon formation of the four lesions in quadrant 2 of Lesion Level 5, the Marker 512 returns to Lesion Level 1. The physician returns to Lesion Level 1, and again rotates the barrel a selected arcuate distance at Lesion Level 1 into alignment with the third quadrant, i.e., by rotating the barrel by ninety degrees.

Guided by the LGUI 506 (see FIG. 15H), the physician again deploys the needle electrodes 48 and performs another lesion generating sequence at quadrant 3 of Level 1. Treatment indicia (e.g., four dots) appear in the quadrant 3 of the graphical segmented disc of Lesion Levels 1, indicating the formation of the four lesions, as well as their spatial orientation in the third quadrant.

As shown in FIG. 15H, guided by the LGUI 506, and following the Marker 512 as it advances with lesion formation at each level, the physician then moves the barrel axially upward in 5 mm increments, sequentially to quadrant 3 of Lesion Level 2, then quadrant 3 of Lesion Level 3, then quadrant 3 of Lesion Level 4, and quadrant 3 of Lesion Level 5. At each Lesion Level, the physician deploys the needle electrodes and performs another lesion generating sequence at quadrant 3 of the respective level. Treatment indicia (e.g., four dots) appear in the third quadrant of the graphical segmented discs of Lesion Levels 2, 3, 4, and 5 (see FIG. 15H), indicating the formation of the four lesions, as well as their spatial orientation in the third quadrant.

The physician repeats the above described sequence one additional time, returning the barrel to Lesion Level 1 and rotating the barrel ninety degrees into alignment with quadrant 4 of Lesion Level 1 (see FIG. 15I). The physician forms the lesion patterns quadrant 4 in the Levels 1, 2, 3, 4, and 5. Treatment indicia (e.g., four dots) appear in the fourth quadrant of the graphical segmented discs of Lesion Levels 1, 2, 3, 4, and 5 (see FIG. 15B), indicating the formation of the four lesions, as well as their spatial orientation in the second quadrant. In addition, with the formation of lesions in the fourth quadrant at each Lesion Level, the graphical disc representing the Lesion Level, each quadrant marked by four dots (indicating completion of lesion creation) is changed to additionally include an indicator, e.g., checkmark, to indicate that the respective Lesion Level has been treated (see FIG. 15I).

As can be appreciated, there are twenty potential treatments with the device. That is, with the device deploying four needles, and ultimately four treatments at each of the Levels 1-5, potentially 80 lesions can be formed. Note that each treatment is preferably timed for sixty seconds, although other cycles/intervals are also contemplated. Note also that each needle electrode can be controlled independently.

As described, the LGUI 506 visually prompts a user in a step-wise fashion to perform a process of forming a pattern of lesions in the anal canal comprising a plurality of axially spaced lesion levels, each lesion level comprising a plurality of circumferential spaced lesions. The LGUI 506 registers the formation of lesions as they are generated in real time, both within and between each circumferentially spaced level. The LGUI 506 displays for the user a visual record of the progress of the process from start to finish and guides the user so that individual lesions desired within a given level are all formed, and that a given level of lesions is not skipped.

Each Lesion Level 1 to 5 of the LGUI 506 is depicted by a first stylized graphical image comprising an edge-tilted disc with a number identification of its level. The discs are segmented corresponding to the regions in which lesions to be formed. There also appears juxtaposed with the next lesion level to be treated, a marker along with a number indicating its distance from the present legion level. As the physician manipulates the device 26 b to form lesions on the indicated levels, the first graphical image further changes to a second graphical image, different than the first image, by adding indicia within the segmented circle to reflect the formation of lesions, to guide the physician as the device is successively operated at the lesion level. Upon forming the desired lesion pattern, the UGUI 506 again changes the second graphical image to a third graphical image, different than the first and second graphical images, comprising an indicator (e.g. a check mark) indicating that all desired lesions have been formed at the level. The Marker 512 is updated to direct the physician to the next Lesion Level. In this way, the UGUI 506 prompts the formation of four lesions sets of four lesions each (totaling twelve lesions) circumferentially spaced apart in the Levels 1, 2, 3, 4, and 5.

During the procedure utilizing either of the radiofrequency treatment devices 26 a or 26 b, certain error messages are graphically indicated on the GUI. Certain of these error messages relate to user errors which could be in the user's control, and therefore could potentially be correctable by the user. For example, if there is an error in the treatment device connection, the generator returns to the set up screen and the icon representing the treatment device displayed by the GUI begins flashing. Another example is if the error relates to the return pad, e.g., improper placement or contact of the pad, the generator likewise returns to the set up screen and the return pad icon displayed by the GUI begins flashing. Another example is if the needles are not treated properly. With these errors indicated, the user can attempt to make the proper adjustments, e.g., check the connection of the treatment device, adjust the position of the return pad, etc. By easily identifying these correctible errors, the system will shut down fewer times thereby enabling the creation of more lesions. Stated another way, the instrument continuously measures temperature which is transmitted back to the generator. The generator expects the temperature to be in a certain range. If the temperature does not appear right, e.g., is outside an expected range, if the RF channel was immediately shut down, then it could result in premature/unnecessary termination of RF energy which could undertreat tissue. Therefore, the present invention provides steps to ensure a shut down result is truly necessary, thus advantageously limiting undertreatment of the tissue. Similarly, if calculated impedance from current measurement does not appear correct, i.e., is outside a desired range, e.g. 50-500 ohms for the instrument of FIG. 6 and 50-100 ohms for the instrument of FIG. 2, the system of the present invention ensures that a channel shut down is warranted before shut down, again avoiding premature/unnecessary termination of RF energy which can result in undertreatment of tissue.

The system, due to its faster processing speed which enables faster processing of data and faster adjustment of parameters, enables rechecking of detected errors to reduce the instances of prematurely shutting down energy flow to an electrode. As discussed above, premature termination of energy flow can result in insufficient application of thermal energy which in turn can result in undertreatment of tissue. In other words, the system advantageously is designed to reduce the number of events that would lead to energy cutoff to an electrode. More specifically, during the treatment cycles, oftentimes an error is detected which can be readily addressed by the user, such as by a small adjustment of the treatment device position if the error is caused for example by patient movement which affects the impedance reading, or even self-adjusts. If the system was designed to immediately shut down upon such error detection, then the electrode would be disabled and the lesion might not be created in that tissue region. Therefore, to reduce these occurrences, the system has been designed to recheck certain errors.

More specifically, for certain detected errors, the system does not permanently interrupt energy flow on the first error reading, but suspends energy flow until a second check of the system is performed. If on the second check the error is no longer detected, energy flow is resumed. However, if on the second check, e.g., re-measurement/calculation, an error still exists, the system runs yet a third check. If the error no longer exists, the energy flow resumes; if the error still exists, energy flow is cut off to that electrode at that treatment position. Consequently, only after the system runs a triple check is a final determinations made to either transition back to energy flow or record the error and disable the electrode channel, i.e., shut down RF energy flow to that electrode. Thus, the error can be checked multiple times to ensure it actually requires interruption of energy flow, thus avoiding premature disabling of an electrode to thereby enhance tissue treatment by not skipping tissue levels, or regions (quadrants) within each tissue level which could otherwise have been treated. As a result, a more comprehensive and uniform tissue treatment is achieved.

This triple error checking feature exemplifies the speed of the processor which enables quicker processing of temperature calculations and quicker response to address rising temperatures so the tissue is not treated above the tissue ablation threshold. As noted above, this tissue ablation threshold can be exceeded if the energy is applied for too long a duration and/or too high a setting such that the tissue temperature rises or applied for too long a duration once the tissue temperature has reached the tissue ablation threshold before the flow of energy is terminated.

Also contributing to preventing overtreatment is to ensure the spacing between the electrodes in manufacture is precise so during application of energy, the amount of overlapping in a circumferential orientation is reduced. Such accurate and consistent spacing can also prevent undertreatment such as if the two of the circumferential array of electrodes are undesirably angled or curved to much toward each other, that would mean they are angled further away from the electrode on the opposite side, possibly creating a gap in the treatment in a circumferential orientation. The axial distance of the electrodes can also affect treatment. Therefore, maintaining the proper axial distance of the electrodes, preferably with the tip terminating at the same distal distance, and maintaining the proper radial distance of the tips, preferably evenly spaced along a circumference, will aid in maintaining the treatment between the lower threshold and maximum threshold, i.e., between undertreatment and overtreatment threshold.

The system, as noted above, also avoids ablating tissue due to careful and more accurate calibration of the tissue temperature measurement mechanism. This is basically achieved by precisely calibrating the PCB so it can read the voltage generated by the thermocouples more accurately, reducing the likelihood of heating tissue beyond the tissue ablation threshold. Thus, the PCB enables more accurate temperature measurements which in turn allows the system to disable or make the appropriate adjustment, e.g., increasing cooling fluid application, when the temperature limits are reached.

While the above description contains many specifics, those specifics should not be construed as limitations on the scope of the disclosure, but merely as exemplifications of preferred embodiments thereof. Those skilled in the art will envision many other possible variations that are within the scope and spirit of the disclosure as defined by the claims appended hereto. 

We claim:
 1. A system for controlling operation of a radiofrequency treatment device to apply radiofrequency energy to tissue to heat tissue to create lesions at a treatment range defined between under heating tissue to fail to achieve a therapeutic affect and overheating tissue to cause tissue ablation, the system comprising a controller including a connector to which a first treatment device having a plurality of electrodes for applying radiofrequency energy to tissue is coupled for use, and a generator for applying radiofrequency energy to the electrodes, the improvement comprising a multiple error checking system which if an error is detected which indicates disabling of an electrode of the plurality of electrodes of the treatment device, the system is configured to check for a repeat of the error and configured to determine if disabling is warranted or energy application is warranted to thereby reduce the likelihood of undertreatment of tissue, and further having temperature sensors associated with the plurality of electrodes and an automatic pump system configured to increase the flow of cooling fluid if measured temperature exceeds a predetermined value to maintain tissue temperature below a tissue ablation threshold.
 2. The system of claim 1, wherein the multiple error checking system is configured to repeat the error check three times.
 3. The system of claim 1, wherein the first treatment device includes a plurality of temperature sensors, the temperature sensors are configured to measure temperature when the electrodes are deployed at the lesion level but prior to application of RF energy to indicate to a user if electrode position needs to be adjusted.
 4. The system of claim 1, wherein the system is configured to detect improper energy flow through a cable and through the electrodes.
 5. The system of claim 1, wherein the system is configured to intermittently check impedance throughout a surgical procedure utilizing the first treatment device.
 6. The system of claim 1, wherein if an error is detected the system is configured to suspend energy flow but does not permanently interrupt energy flow until the error is rechecked.
 7. A system for controlling operation of a radiofrequency treatment device to apply radiofrequency energy to tissue to heat tissue to create lesions at a treatment range defined between under heating tissue to fail to achieve a therapeutic effect and overheating tissue to cause ablation of tissue, the system comprising a controller including a connector to which a first treatment device having a plurality of electrodes for applying radiofrequency energy to tissue is coupled for use, and a generator for applying radiofrequency energy to the electrodes, the controller configured to control application of energy so that the tissue is thermally treated to create lesions but prevent thermal treatment beyond a threshold which would ablate the tissue, the system further including a cut off function to cut off energy flow to disable an electrode of the plurality of electrodes if one of multiple potential errors is detected, the system further containing a feature to prevent premature disabling of an electrode of the plurality of electrodes, and further including an automatic pump system to increase the flow of cooling fluid if measured temperature exceeds a predetermined value.
 8. The system of claim 7, wherein the feature to prevent premature disabling of the electrode comprises a multiple error check in which if an error is detected, a measurement is rechecked to determine if the error is still present before cut off of the energy flow.
 9. The system of claim 7, further comprising an operation system configured to execute on a display screen a first graphical interface guiding use of the first treatment device coupled to the controller, the controller configured to visually prompt a user in a step-wise fashion to perform a process using the coupled treatment device of forming a pattern of lesions in a body region in a plurality of axially spaced lesion levels, each lesion level including a plurality of circumferential spaced lesions.
 10. The system of claim 7, wherein the first treatment device includes a three dimensional basket and an expandable balloon within the basket to expand the basket, the basket including a plurality of spines and the plurality of electrodes are movable within the plurality of spines.
 11. The system of claim 7, wherein the electrodes have penetrating tips to penetrate tissue.
 12. The system of claim 7, wherein if the measured temperature reaches a second predetermined value, the pump system is configured to automatically move to its maximum pump speed and cannot be overridden by a user.
 13. The system of claim 12, wherein if a third higher value is reached, the electrode is disabled, and further comprising an indicator to indicate if the electrode is disabled.
 14. The system of claim 7, wherein the first treatment device includes a handle and a shielded printed circuit board contained in the handle, the printed circuit board enabling precise measurement of tissue and electrode parameters to regulate tissue temperature to prevent thermal treatment of tissue beyond a tissue ablation threshold, and the shield configured to reduce interference to minimize unwanted disabling of electrodes.
 15. The system of claim 14, wherein the printed circuit is asymmetrically mounted within the handle.
 16. The system of claim 14, wherein the printed circuit board includes a coded identification for the first treatment device.
 17. The system of claim 7, wherein a coded identification for the first treatment device is positioned in the handle and a printed circuit board for temperature calculation is positioned outside the handle.
 18. The system of claim 7, wherein if an error is detected the system is configured to suspend energy flow but does not permanently interrupt energy flow until the error is rechecked.
 19. The system of claim 7, further comprising temperature sensors associated with the plurality of electrodes. 